Reduction of Particle and Heat Transport in HSX with Quasisymmetry
description
Transcript of Reduction of Particle and Heat Transport in HSX with Quasisymmetry
DPP 2006
Reduction of Particle and Heat Transport Reduction of Particle and Heat Transport in HSX with Quasisymmetryin HSX with Quasisymmetry
J.M. Canik, D.T.Anderson, F.S.B. Anderson, K.M. Likin, J.N. Talmadge, K. Zhai
HSX Plasma Laboratory, University of Wisconsin-Madison, USA
DPP 2006
OutlineOutline• HSX operational configurations for studying transport with and
without quasisymmetry
• Particle Transport– Hα measurements and neutral gas modeling give plasma source rate– Without quasisymmetry, density profile is hollow due to thermodiffusion– With quasisymmetry, density profiles are peaked
• Electron Thermal Transport– Power absorption is measured at ECRH turn-off using Thomson scattering– With quasisymmetry, electron temperature is higher for fixed power– Reduction in core electron thermal diffusivity is comparable to neoclassical
prediction
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HSX: The Helically Symmetric ExperimentHSX: The Helically Symmetric Experiment
Major Radius 1.2 m
Minor Radius 0.12 m
Number of Field Periods
4
Coils per Field Period
12
Rotational Transform
1.05 1.12
Magnetic Field 0.5 T
ECH Power (2nd Harmonic)
<100 kW 28 GHz
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HSX is a Quasihelically Symmetric StellaratorHSX is a Quasihelically Symmetric Stellarator
QHS Magnetic Spectrum
QHS
HSX has a helical axis of symmetry in |B|
Very low level of neoclassical transport
εeff ~ .005
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Symmetry can be Broken with Auxiliary CoilsSymmetry can be Broken with Auxiliary Coils• Aux coils add n=4 and 8, m=0 terms to the magnetic spectrum
– Called the Mirror configuration– Raises neoclassical transport towards that of a conventional stellarator
• Other magnetic properties change very little compared to QHS– Axis does not move at ECRH/Thomson scattering location
• Favorable for heating and diagnostics
QHS Mirror
Transform (r/a = 2/3) 1.062 1.071
Volume (m3) 0.384 0.355
Axis location (m) 1.4454 1.4447
Effective Ripple 0.005 0.040
< 1 mm shiftfactor of 8
< 10%< 1%
Mirror Magnetic Spectrum
εeff ~ .04 Change:
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Neoclassical Transport is Reduced in the Neoclassical Transport is Reduced in the Quasisymmetric ConfigurationQuasisymmetric Configuration
• Monoenergetic diffusion coefficients calculated with Drift Kinetic Equation Solver (DKES*)
• Data is fit to an analytic form, including 1/ν, ν1/2, and ν regimes of low-collisionality transport
• Integration over Maxwellian forms thermal transport matrix
k
kk
k
rkkkk
k
kk
k
rkkk
TTD
TEq
nnDnTQ
TTD
TEq
nnDn
'
22
'
21
'
12
'
11
*W.I. van Rij and S.P. Hirshman, Phys. Fluids B 1, 563 (1989).
Mirror
QHS
Er
HSX Parameters
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The Ambipolar Electric Field has a Large The Ambipolar Electric Field has a Large Effect on Neoclassical TransportEffect on Neoclassical Transport
• Electric field is determined by ambipolarity constraint on neoclassical fluxes
• This has up to three solutions: the ion and electron roots, and an unstable intermediate root
iie Z
Te ~ Ti
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The Ambipolar Electric Field has a Large The Ambipolar Electric Field has a Large Effect on Neoclassical TransportEffect on Neoclassical Transport
• Electric field is determined by ambipolarity constraint on neoclassical fluxes
• This has up to three solutions: the ion and electron roots, and an unstable intermediate root
• In HSX plasmas Te >> Ti
– In Mirror, only electron root exists– Large electric field reduces Mirror
transport, masks neoclassical difference with quasisymmetric field
HSX Parameters:Te >> Ti
iie Z
Te ~ Ti
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Particle Source is Calculated with DEGASParticle Source is Calculated with DEGAS• DEGAS* uses Monte Carlo method
to calculate neutral distribution– Gives neutral density, particle source
rate, Hα emission, etc.
• 3D HSX geometry is used in calculations, along with measured n and T profiles
• Two gas sources are included– Gas valve as installed on HSX– Recycling at locations where field
lines strike wall– Magnitude of gas source rate must
be specified
*D. Heifetz et al., J. Comp. Phys. 46, 309 (1982)
Molecular Hydrogen Density:Plasma Cross Section
Gas Puff3D View
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DEGAS Calculations are Calibrated to HDEGAS Calculations are Calibrated to Hαα MeasurementsMeasurements
• HSX has a suite of absolutely calibrated Hα detectors– Toroidal array: 7 detectors distributed
around the machine– Radial array: 9 detectors viewing cross
section of plasma
• Gas puff rate input to DEGAS is scaled so that DEGAS Hα emission matches experiment at one detector– Results in good agreement in profiles of
Hα brightness– Toroidal array used for recycling
contribution
• Hα measurements + modeling yields the particle source rate density total radial particle flux
NormalizationPoint
Hα Chord 98 7 6 5
43
2
1
Gas Valve
Vessel WallPlasma
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Mirror Plasmas Show Hollow Density ProfilesMirror Plasmas Show Hollow Density Profiles• Thomson scattering profiles shown for Mirror plasma
– 80 kW of ECRH, central heating
• Density profile in Mirror is similar to those in other stellarators with ECRH: flat or hollow in the core– Hollow profile also observed using 9-chord interferometer– Evidence of outward convective flux
Te(0) ~ 750 eV
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Neoclassical Thermodiffusion Accounts for Neoclassical Thermodiffusion Accounts for Hollow Density Profile in Mirror ConfigurationHollow Density Profile in Mirror Configuration
• Figure shows experimental and neoclassical particle fluxes– Experimental from Hα/DEGAS– Neoclassical from DKES calculations
• In region of hollow density profile, neoclassical and experimental fluxes comparable
• The T driven neoclassical flux is dominant
TTD
TqE
nnDn r
12
'
11
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Off-axis Heating Confirms Thermodiffusive Off-axis Heating Confirms Thermodiffusive Flux in MirrorFlux in Mirror
• With off-axis heating, core temperature is flattened
• Mirror density profile becomes centrally peaked
ECH Resonance
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Off-axis Heating Confirms Thermodiffusive Off-axis Heating Confirms Thermodiffusive Flux in MirrorFlux in Mirror
• With off-axis heating, core temperature is flattened
• Mirror density profile becomes centrally peaked
ECH Resonance
On-axis heating
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Quasisymmetric Configuration has Peaked Quasisymmetric Configuration has Peaked Density Profiles with Central HeatingDensity Profiles with Central Heating
• Both the temperature and density profiles are centrally peaked in QHS– Injected power is 80 kW; same as Mirror case– Thermodiffusive flux not large enough to cause hollow profile
TTD
TqE
nnDn r
12
'
11D12 is smaller due to quasi-symmetry
Te(0) ~ 1050 eV
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Neoclassical Particle Transport is Dominated Neoclassical Particle Transport is Dominated by Anomalous in QHSby Anomalous in QHS
• Neoclassical particle flux now much less than experiment– Experiment 10 times larger than
neoclasical at r/a=0.3– Core particle flux still large due to strong
Te and ne gradients
• Large core fuelling inward convection not necessary for peaked profile
ne
Source Rate
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Electron Temperature Profiles can be Well Electron Temperature Profiles can be Well Matched between QHS and MirrorMatched between QHS and Mirror
• To get the same electron temperature in Mirror as QHS requires 2.5 times the power– 26 kW in QHS, 67 kW in Mirror– Density profiles don’t match because of thermodiffusion in Mirror
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The Bulk Absorbed Power is MeasuredThe Bulk Absorbed Power is Measured
• The power absorbed by the bulk is measured with the Thomson scattering system– Time at which laser is fired is varied over many similar discharges– Decay of kinetic stored energy after turn-off gives total power absorbed
by the bulk, rather than by the tail electrons• At high power, HSX plasmas have large suprathermal electron population (ECE, HXR)
QHS has 50% improvement in confinement time: 1.7 vs. 1.1 ms
QHS Mirror
Pinj 26 kW 67 kW
Pabs 10 kW 15 kW
Wkin 17 J 17J
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Transport Analysis has been Performed using Transport Analysis has been Performed using Ray Tracing and Measured PowerRay Tracing and Measured Power
• Total absorbed power is taken from Thomson scattering measurement
• Absorbed power profile is based on ray-tracing– Absorption localized within r/a~0.2– Very similar profiles in the two
configurations
• Convection, radiation, electron-ion transfer are negligible (~10% of total loss inside r/a~0.6)
• Effective electron thermal diffusivity is calculated
e
ee
r
abse
Tnq
rdrprr
q
0
1
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Thermal Diffusivity is Reduced in QHSThermal Diffusivity is Reduced in QHS
• QHS has lower core χe
– At r/a ~ 0.25, χe is 2.5 m2/s in QHS, 4 m2/s in Mirror
– Difference is comparable to neoclassical reduction (~2 m2/s)
• Two configurations have similar transport outside of r/a~0.5
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ConclusionsConclusions
• Quasisymmetry has a large impact on plasma profiles– Density profiles are peaked with quasisymmetry, hollow
when symmetry is broken – Quasisymmetry leads to higher electron temperatures
• These differences are due to reduced neoclassical transport with quasisymmetry– Hollow profile is due to thermodiffusion – reduced with
quasisymmetry– Reduction in thermal diffusivity is comparable to neoclassical
prediction